Information storage medium and method and apparatus for recording/reproducing data on/from the same

ABSTRACT

An information storage medium and a method and apparatus for recording/reproducing data on/from the information storage medium. The information storage medium includes a plurality of recording layers, each having a user data area, on which data can be recorded by a pickup. Data is recorded in the order of recording layers from closest to farthest from the pickup, and a recordable region in a user data area of a recording layer on which data is to be recorded is smaller than that in a recording layer between the pickup and the recording layer on which data is to be recorded. Each recording layer contains a recordable region in a user data area and a optimum power control (OPC) area in order to maintain the same recording/reproducing characteristics between the plurality of recording layers.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation application of U.S. patent application Ser. No. 11/012,185, filed Dec. 16, 2004, currently pending, which claims the priority of Korean Patent Application No. 2004-29187, filed on Apr. 27, 2004 in the Korean Intellectual Property Office, the disclosures of which are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an information storage medium and a method of and an apparatus for recording/reproducing data on/from the information storage medium. More particularly, the present invention relates to an information storage medium with a plurality of recording layers and which is designed to maintain the same recording/reproducing characteristics between the plurality of recording layers, each layer having recordable regions in user data area and an optimum power control (OPC) area for performing a test to determine optimum recording power, and a method of and an apparatus for recording/reproducing data on/from the information storage medium.

2. Description of the Related Art

An optical pickup performs non-contact recording/reproducing to/from an information storage medium. Optical disks that are one type of information storage media are classified into compact disks (CDs) and digital versatile disks (DVDs) depending on data recording capacity. Examples of optical disks capable of writing and reading information include CD-Recordable (CD-R), CD-Rewritable (CD-RW), and 4.7 GB DVD+RW. Furthermore, a high definition-DVD (HD-DVD) or blu-ray disk (BD) with recording capacity of over 15 GB and a super-resolution optical disk that can read data recorded in a pattern of marks below the resolution limit are currently being developed.

While only single layer 4.7 GB DVD-Recordable discs are commercially available, dual layer 8.5 GB DVD-ROM discs are being sold in the market. To back up data recorded on the 8.5 GB DVD-ROM disc, a DVD-Recordable disc with the 8.5 GB capacity is required. Thus, there is a need for a recordable disc having at least first and second recording layers.

When recording data on a recordable disc with first and second recording layers, the first recording layer must maintain the same recording/reproducing characteristics as the second recording layer in order to improve recording/reproducing performance. That is, variations in recording/reproducing characteristics depending on the recording sequence may adversely affect the recording/reproducing by a drive. Thus, there is a need for methods of maintaining the same recording/reproducing characteristics between a plurality of recording layers.

SUMMARY OF THE INVENTION

The present invention provides a method of and an apparatus for recording/reproducing data on/from a recordable information storage medium having a plurality of recording layers such that each recording layer has the same recording/reproducing characteristics and an information storage medium on which data is recorded by the same method and apparatus.

According to an aspect of the present invention, there is provided an information storage medium including a plurality of recording layers, each having a user data area, on which data is recordable by a pickup. In the information storage medium, data is recorded in the order of recording layers from closest to farthest from the pickup, and a recordable region in a user data area of a recording layer on which data is being recorded is smaller than a recordable region in a recording layer between the pickup and the recording layer on which data is being recorded.

In another embodiment, the present invention provides an information storage

Medium including a plurality of recording layers, each having an optimum power control (OPC) area for performing a test in order to determine optimum recording power, on which data is recordable by a pickup. In the information storage medium, data is recorded in the order of recording layers from closest to farthest from the pickup, and a recordable region in an OPC area of a recording layer on which data is being recorded is smaller than that in a recording layer between the pickup and the recording layer on which data is being recorded.

The recording layer includes unrecorded regions on the inner and outer circumferences of a user data area, wherein each unrecorded region corresponds to about half the number of tracks contained in a recording beam passing through the outer layer. ${{Number}\quad{of}\quad{unrecorded}\quad{tracks}} = \frac{{SL}\quad{\tan\left\lbrack {\sin^{- 1}\left( \frac{NA}{n} \right)} \right\rbrack}}{TP}$ where the unrecorded region contains the number of tracks, and SL, TP, NA, and n denote the thickness of a spacer layer between the plurality of recording layers, a track pitch, a numerical aperture of an objective lens, and a refractive index of the information storage medium, respectively. The size of a recorded region of each of the plurality of recording layers may decrease as a recording layer moves farther away from the pickup.

According to another aspect of the present invention, there is provided a method for recording/reproducing data on a recordable information storage medium with a plurality of recording layers using a pickup.

In another embodiment, the present invention provides a method for recording/reproducing data on a recordable information storage medium including a plurality of recording layers using a pickup, each recording layer having an optimum power control (OPC) area for performing a test in order to determine optimum recording power. The method includes the steps of recording data on a recording layer located closest to the pickup and recording data whose capacity decreases in the order of recording layers from closest to farthest from the pickup.

According to another aspect of the present invention, there is provided an apparatus for recording/reproducing data on/from a recordable information storage medium including a plurality of recording layers. The apparatus includes: a pickup that irradiates a beam onto the information storage medium; a recording/reproducing signal processor that receives a beam reflected from the information storage medium through the pickup for signal processing; and a controller that controls the pickup to record data in the order of recording layers from closest to farthest from the pickup and not to record data on predetermined regions located on the inner and outer circumferences of a user data area of a recording layer on which data is being recorded except a recording layer closest to the pickup.

In another embodiment, the present invention provides an apparatus for recording/reproducing data on/from a recordable information storage medium including a plurality of recording layers, each recording layer having an optimum power control (OPC) area for performing a test in order to determine optimum recording power. The apparatus includes: a pickup that irradiates a beam onto the information storage medium; a recording/reproducing signal processor that receives a beam reflected from the information storage medium through the pickup for signal processing; and a controller that controls the pickup to record data in the order of recording layers from closest to farthest from the pickup and not to record data on predetermined regions located on the inner and outer circumferences of an OPC area of a recording layer on which data is being recorded except a recording layer closest to the pickup.

Additional aspects and/or advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other features and/or other aspects and advantages of the present invention will become more apparent and more readily appreciated from the following description of the embodiments taken in conjunction with the accompanying drawings in which:

FIG. 1 illustrates a layout of a dual layer information storage medium for explaining a method of recording/reproducing data on/from an information storage medium according to the present invention;

FIG. 2 is a schematic diagram of an apparatus for recording/reproducing data on/from an information storage medium according to an embodiment of the present invention;

FIG. 3 illustrates a schematic layout of a dual layer information storage medium according to a first embodiment of the present invention;

FIG. 4 illustrates a schematic layout of a quadruple layer information storage medium according to the first embodiment of the present invention;

FIG. 5 illustrates a schematic layout of a dual layer information storage medium according to a second embodiment of the present invention;

FIG. 6 illustrates a schematic layout of a quadruple layer information storage medium according to the second embodiment of the present invention; and

FIGS. 7A and 7B are layouts for explaining a method of performing a test on an information storage medium according to the present invention to determine optimum recording power.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout. The embodiments are described below to explain the present invention by referring to the figures.

A method of recording/reproducing data on/from an information storage medium having a plurality of recording layers according to the present invention allows data to be prerecorded on a portion of another recording layer through which a recording beam passes when irradiating a target recording layer with the beam to record the data.

A recordable information storage medium performs optimum power control (OPC) prior to recording data in order to find the optimal recording power. To perform OPC, data is written in an OPC area at a predetermined recording power and read back to test the reproducing characteristics. Before performing OPC, data is recorded on a region through which a beam for OPC passes.

When OPC is implemented in a recordable information storage medium having a plurality of recording layers, recording/reproducing characteristics after recording data may vary from one recording layer to another, for example, depending on the recording sequence or recording power. Since these variations may lead to inaccuracy in OPC, it is necessary to detect conditions that may cause recording/reproducing characteristics to change depending on the state of each recording layer and perform OPC considering the detected conditions.

To find conditions that affect the data recording/reproducing characteristics, experiments were made to write data on an information storage medium having first and second recording layers L1 and L2 as shown in FIG. 1 in a different order and at different recording power levels.

Recording conditions of the information storage medium are a linear velocity of 3.8 m/s, laser wavelength of 650 nm, and objective lens numerical aperture (NA) of 0.60. The information storage medium uses multipulse. That is, while recording power of 15.1 mW, Ttop of 1.45 T, Tmp of 0.65 T, and Tdtp 3T of −0.03T are used for the first recording layer L1, recording power of 20 mW, Ttop of 1.65T, Tmp of 0.70T, Tdtp 3T of −0.03T are used for the second recording layer L2. Ttop, Tmp, and Tdtp denote the duration of a top pulse, the duration of each pulse in the multipulse train, and time shifted from reference, respectively. A negative sign (−) in Tdtp means Tdtp is shifted to the left. Here, basic recording conditions are set as recording power and write strategy adjusted for minimum jitter by writing data only on a desired recording layer, and 1T denotes 38.5 ns.

Table 1 shows jitters, I3/I14 (modulations), asymmetries, and reflectivities measured after writing data on the first and second recording layers L1 and L2 under the above-mentioned conditions. As shown in FIG. 1, a pickup is located closer to the first recording layer L1, and reference numeral 10 denotes an objective lens. TABLE 1 First recording layer (L1) Second recording layer (L2) Recording Jitte I3/I1 Asymmet Reflectiv Jitte I3/I1 Asymmet Reflectivity Recording state L1 7.9% 0.270 0.085 17.0% 8.1% 0.255 0.030 17.5% L1 unrecorded, unrecorded, L2 recorded Recording L2 8.0% 0.250 0.098 16.8% 8.3% 0.240 0.023 18.9% Recording L1 after recording after recording Recording L1 8.1% 0.267 0.091 16.5% 8.9% 0.244 0.060 18.8% Recording L2 after recording after recording

As is evident from Table 1, the first recording layer L1 maintains almost the same values of jitter, I3/I14, asymmetry, and reflectivity regardless of the recording state or sequence while the second recording layer L2 exhibits varying characteristics depending on the recording sequence. That is, when data is written sequentially from the first recording layer L1 to the second recording layer L2, the second recording layer L2 suffers from large variations in jitter, asymmetry, and reflectivity. When data is written in the reverse order, the second recording layer L2 suffers from less variation in these characteristics.

Thus, to reduce variations in the recording/reproducing characteristics, data must be sequentially recorded from the first recording layer L1 to the second recording layer L2. Furthermore, data has been recorded on a region of the first recording layer L1 through which a recording beam passes before recording data on the second recording layer L2.

Table 2 shows recording/reproducing characteristics measured after data is written at recording powers that are 120% and 150% of the normal power. During OPC, a test is performed at different recording power levels to determine an optimum recording power value. In particular, since the information storage medium once used for a predetermined period of time may require recording power to be higher than normal power due to surface contamination, it is necessary to perform the test at higher power. TABLE 2 First recording layer (L1) Second recording layer (L2) Recording state Jitte I3/I1 Asymmet Reflectiv Jitte I3/I1 Asymmet Reflectiv Recording state Recording L1 8.2% 0.259 0.097 16.3% 9.3% 0.250 0.052 18.8% Recording L2 after after recording recording L1 Recording L1 8.2% 0.272 0.096 16.4% 9.8% 0.261 0.060 19.1% Recording L2 after after recording recording L1

As is evident from Table 2, while the first recording layer L1 exhibits almost the same recording/reproducing characteristics even at higher recording powers, the second recording layer L2 suffers from great variations in reflectivity, asymmetry, and jitter when data is written sequentially on the first and second recording layers L1 and L2. As compared against recording at normal power, the jitter increases but reflectivity and asymmetry remains almost constant.

As shown in Tables 1 and 2 above, the first recording layer L1 is little affected by recording sequence or recording power whereas the second recording layer L2 is significantly affected by the same. In particular, when data is written sequentially on the first and second recording layers L1 and L2, the second recording layer L2 suffers from great variations in the recording/reproducing characteristics. These variations result from transmittance that may change depending on whether a recording beam passes through a recorded or unrecorded portion of a recording layer. Low transmittance reduces the effect of recording power.

Meanwhile, it is necessary to perform a test under the conditions that cause great variations in recording/reproducing characteristics. That is, if there is little change in the recording/reproducing characteristics under any conditions, it is possible to find the accurate optimum recording power without any special test conditions for determining the same. However, if the recording/reproducing characteristics vary according to the recording conditions, a test needs to be performed under conditions that cause large variations in the characteristics in order to determine the optimum recording power.

Thus, when a test beam is emitted in order to find the optimum recording power, it is preferable that data has been written on at least a portion of a recording layer through which the test beam passes.

Referring to FIG. 1, an information storage medium according to the present invention includes a first recording layer L1 comprising a lead-in area 10-L1, a user data area 20-L1, and a lead-out area 30-L1, a second recording layer L2 comprising a lead-in area 10-L2, a user data area 20-L2, and a lead-out area 30-L2, and a space layer 15 interposed between the first and second recording layers L1 and L2. Before recording data or performing OPC on the second recording layer L2, data is recorded on a portion of the first recording layer L1 through which a recording or test beam passes.

Referring to FIG. 2, an information storage medium D includes first and second recording layers L1 and L2, and a pickup 50 for recording data is disposed adjacent the first recording layer L1. Before a recording beam or a test beam is irradiated in order to record data or perform OPC on the second recording layer L2, respectively, data is recorded on a portion of the first recording layer L1 through which the recording beam or the test beam passes. In this case, data may be recorded on tracks contained in the portion of the first recording layer L1 through which the recording beam or the test beam passes.

Referring to FIG. 1, a number of tracks on the first recording layer L1 irradiated by the test beam when recording on the second recording layer L2 is given by Equation (1): $\begin{matrix} {{{Number}\quad{of}\quad{Tracks}} = {\frac{2X}{TP} = \frac{2{SL}\quad\tan\quad\theta}{TP}}} & (1) \end{matrix}$ where X is one-half the diameter of test beam at the first recording layer, and Θ is one-half the included angle of the light beam as shown in FIG. 1, SL and TP denote the thickness of the space layer 15 between the first and second information storage layers L1 and L2 and a track pitch, respectively.

When n and NA denote a refractive index of the information storage medium and a numerical aperture of the objective lens 10, respectively, using relational expression NA=nsinθ, Equation (1) may be rewritten as Equation (2): $\begin{matrix} {{{Number}\quad{of}\quad{Tracks}} = \frac{2{SL}\quad{\tan\left\lbrack {\sin^{- 1}\left( \frac{NA}{n} \right)} \right\rbrack}}{TP}} & (2) \end{matrix}$

Data may be written on an area of the first recording layer L1 corresponding to the number of tracks defined by Equation (2) before irradiating the second recording layer L2 with a test beam for OPC or a recording beam. Where SL tanθ=41.25 (μm) and TP=0.74 μm, the number of tracks contained in the recording beam or the test beam is about 112.

Meanwhile, referring to FIG. 3, user data area 20-L2 may include unrecorded regions on the innermost and outermost circumferences, each region containing a number X of tracks affected by the first recording layer L1 when recording data on the second recording layer L2 as described above.

Thus, a recorded region in the user data area 20-L2 of the second recording layer L1 is smaller than that in the user data area 20-L1 of the first recording layer L1. More specifically, data are not recorded to regions containing X tracks on the inner and outer circumferences of the user data area 20-L2. The number X of tracks is given by Equation (3): $\begin{matrix} {{{Number}\quad{of}\quad{tracks}\quad{corresponding}\quad{to}\quad X} = \frac{{SL}\quad{\tan\left\lbrack {\sin^{- 1}\left( \frac{NA}{n} \right)} \right\rbrack}}{TP}} & (3) \end{matrix}$

Thus, the number of tracks corresponding to X on the second recording layer L2 is one-half the number of tracks through which the light beam passes at the first recording layer. While FIG. 3 shows the dual layer information storage medium with the first and second recording layers L1 and L2, the same structure is applicable to an information storage medium having three or more recording layers.

Referring to FIG. 4, an information storage medium includes a first recording layer L1 comprising a lead-in area 10-L1, a user data area 20-L1, and a lead-out area 30-L1, a second recording layer L2 comprising a lead-in area 10-L2, a user data area 20-L2, and a lead-out area 30-L2, a third recording layer L3 comprising a lead-in area 10-L3, a user data area 20-L3, and a lead-out area 30-L3, and a fourth recording layer L4 comprising a lead-in area 10-L4, a user data area 20-L4, and a lead-out area 30-L4. Data are not recorded on regions located on the inner and outer circumferences of the user data areas 20-L2, 20-L3, and 20-L4, the regions containing X1, X2, and X3 tracks, respectively.

Here, the size of a recorded region in a user data area decreases as a recording layer is farther away from a surface on which a beam is incident. In other words, the size of an unrecorded region increases as a recording layer is farther away from the surface on which the beam is incident (X3>X2>X1).

While the size of a recorded region varies for each recording layer as described above, the size of recorded regions in user data areas of the remaining recording layers may be made equal to that in the user data area of a recording layer farthest away from the surface on which the recording beam is incident. For example, when data is not recorded on regions on the inner and outer circumferences of the user data area 20-L4 in the fourth recording layer L4, each region containing X3 tracks, data may not be recorded on regions located on the inner and outer circumferences of the second and third recording layers L2 and L3, each region containing X3 tracks.

FIG. 5 illustrates a schematic layout of a dual layer information storage medium according to a second embodiment of the present invention. Referring to FIG. 5, an information storage medium includes first and second recording layers L1 and L2, and the size of a recorded region in a user data area decreases as a recording layer is farther away from the surface on which a beam is incident. Furthermore, the sizes of a lead-in area and a lead-out area each increase as the recording layer is farther away from the surface on which a beam is incident. That is, when a recording beam or a test beam is incident first on the first recording layer L1, a user data area 20-L1 on the first recording layer L1 is larger than a user data area 20-L2 on the second recording layer L2, and a lead-in area 10-L1 and a lead-out area 30-L1 on the first recording layer L1 each are smaller than the counterparts 10-L2 and 30-L2 on the second recording layer L2. The user data area 20-L2 on the second recording layer L2 may be equal to the user data area 20-L1 on the first recording layer L1 minus areas corresponding to X on the inner and outer circumferences of the user data area 20-L1.

The same structure is also applicable to an information storage medium having three or more recording layers. FIG. 6 illustrates a schematic layout of a quadruple layer information storage medium including first through fourth recording layers L1-L4 according to a second embodiment of the present invention. When a recording beam is first incident on the first recording layer L1, the size of a user data area decreases as a recording layer moves farther away from the surface on which the beam is incident (20-L1>20-L2>20-L3>20-L4) while the sizes of lead-in area and lead-out area each increase as a recording layer moves farther away from the same direction (10-L1<10-L2<10-L3<10-L4 and 30-L1<30-L2<30-L3<30-L4).

Meanwhile, referring to FIG. 7A, first and second recording layers L1 and L2 respectively include OPC regions 13-L1 and 13-L2 in either or both lead-in and lead-out areas. Before performing OPC on a desired recording layer, data is recorded on at least a portion of a recording layer through which a test beam for finding optimum recording power passes.

A recorded region in an OPC area of a desired recording layer is smaller than that in an OPC area of the underlying recording layer. Referring to FIG. 7A, for example, a recorded region 14-L2 in the OPC area 13-L2 of the second recording layer L2 is smaller than a recorded region 14-L1 in the OPC area 13-L1 of the first recording layer L1. An unrecorded region in the OPC area 13-L2 corresponds to the number of tracks X (See Equation (3)) contained in a test beam.

Alternatively, the first and second recording layers L1 and L2 each may have OPC areas separately from a lead-in area and a lead-out area. For example, the OPC areas each may be located inside the lead-in area and outside the lead-out area.

The location of a recorded region 14-L2 in an OPC area 13-L2 of a second recording layer L2 shown in FIG. 7B is different from that shown in FIG. 7A.

According to a method for recording/reproducing data on/from an information storage medium having a plurality of recording layers according to a preferred embodiment of the present invention, data is recorded using a pickup in the order of recording layers from closest to farthest from the pickup.

The size of a recorded region in a user data area decreases in the order of recording layers from closest to farthest from the pickup. Each recording layer also has a lead-in area and a lead-out area on the inner and outer circumferences of a user data area, respectively, whose sizes increase as the recording layer is farther away from the pickup.

Alternatively, data may be recorded on a user data area of a recording layer on which a recording beam is first incident and then on a user data area of an overlying recording layer except for the inner and outer circumferences. Thereby, the size of a recorded region in a user data area may decrease farther away from the recording layer on which the recording beam is first incident.

When performing an OPC test before recording user data, data for the test is recorded in the order of recording layers from closest to farthest from the pickup. Except for a recording layer closest to the pickup, data is not recorded on predetermined regions located on the inner and outer circumferences of an OPC area of the recording layer on which a write operation is about to begin. Therefore, the size of a recorded region in an OPC area decreases as a recording layer is farther away from the pickup.

In a DVD-ROM drive, a pickup is disposed adjacent a first recording layer and data is written from the first recording layer to the second recording layer. To maintain consistency with the DVD-ROM disk, the recordable information storage medium according to the present invention may be arranged to allow data to sequentially be recorded from the first recording layer L1 to the second recording layer L2.

The same method for recording/reproducing data according to the present invention is applicable when the pickup is located adjacent the second recording layer L2. That is, data is first recorded on the second recording layer L2. Before performing OPC for recording on the first recording layer L1, data is recorded on at least a portion of the second recording layer L2 through which a test beam passes.

Furthermore, the method is applicable to both opposite track path (OTP) and parallel track path (PTP) disks. While the present invention has been described with reference to a dual layer information storage medium, the method is applicable to a multi-layer medium having three or more recording layers.

Referring to FIG. 2, an apparatus (i.e., a disk drive) for recording/reproducing data on/from an information storage medium D according to an embodiment of the present invention includes a pickup 50, a recording/reproducing signal processor 60, and a controller 70. More specifically, the pickup 50 includes a laser diode 51 that emits a beam, a collimating lens 52 that collimates the beam emitted by the laser diode 51 to a parallel beam, a beam splitter 54 that changes the propagation path of an incident beam, and an objective lens 56 that focuses the beam passing through the beam splitter 54 onto the information storage medium D.

The beam reflected from the information storage medium D is reflected by the beam splitter 54 and is incident on the photodetector 57 (e.g. a quadrant photodetector). The beam received by the photodetector 57 is converted into an electrical signal by an operational circuit 58 and output as an RF or sum signal through channel Ch1 and as a push-pull signal through a differential signal channel Ch2.

The controller 70 controls the pickup 50 to record data and to reduce data area in the order of recording layers from closest to farthest from the pickup 50. Also, the controller 70 controls the pickup 50 not to record data on predetermined regions located on the inner and outer circumferences of a user data area of a recording layer on which data is being recorded except the recording layer closest to the pickup 50. Alternatively, the sizes of a lead-in area and a lead-out area may increase in the order of recording layers from closest to farthest from the pickup 50. Here, the size of an unrecorded region or a difference in the capacity of data to be recorded on a user data area between adjacent recording layers may correspond to the number X of tracks that passes over a recording beam as described above.

The controller 70 performs a test on a test area in the information storage medium D to determine the optimum recording power before recording on the information storage medium D having the first and second recording layers L1 and L2. The controller 70 also controls the pickup 50 not to record data on predetermined regions located on the inner and outer circumferences of an OPC area of a recording layer on which data is being recorded during OPC except for a recording layer on which data is recorded for the first time.

The controller 70 allows a recording beam to be irradiated from the pickup 50 at normal power obtained during the test, so that data may be recorded on the information storage medium D using the recording beam.

In order to reproduce the thus recorded data, a beam reflected from the information storage medium D passes through the objective lens 56 and the beam splitter 54 and is incident on the photodetector 57. The beam input to the photodetector 57 is then converted into an electrical signal by the operational circuit 58 and output as an RF signal.

A method and apparatus for recording/reproducing data on/from a recordable information storage medium with a plurality of recording layers according to the present invention prevent data from being recorded on the inner and outer circumferences of a user data area of each recording layer, thereby providing the same recording/reproducing characteristics across the entire user data area.

The present invention makes it possible to obtain the accurate optimum recording power by applying the same method in performing an OPC test. Furthermore, the present invention provides a recordable information storage medium designed to maintain consistency with DVD-ROM by allowing data to be recorded/reproduced in the order of recording layers from closest to farthest from a pickup.

Using the apparatus in recording/reproducing data on/from the recordable information storage medium improves the recording/reproducing performance of the information storage medium while making it possible to accurately perform a test to determine optimum recording power.

Although a few embodiments of the present invention have been shown and described, it would be appreciated by those skilled in the art that changes may be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the claims and their equivalents. 

1. A reproducing apparatus comprising: a pickup that irradiates a beam with respect to an information storage medium, the information storage medium including a first recording layer and a second recording layer disposed between the pickup and the first recording layer; and a controller that controls the pickup to reproduce data from user data areas on the first and second recording layers, wherein a size of a recordable region in the user data area of the first recording layer is smaller than a recordable region in the user data area of the second recording layer.
 2. The apparatus of claim 1, wherein the first recording layer comprises unrecorded regions on inner and outer circumferences of the user data area, wherein each unrecorded region corresponds to about one-half a number of tracks through which a recording beam would pass on the second recording layer to record information on the first recording layer.
 3. The apparatus of claim 1, wherein the first recording layer comprises unrecorded regions on inner and outer circumferences of the user data area, wherein each unrecorded region comprises about a number of tracks determined according to an equation: ${{Number}\quad{of}\quad{tracks}} = \frac{{SL}\quad{\tan\left\lbrack {\sin^{- 1}\left( \frac{NA}{n} \right)} \right\rbrack}}{TP}$ where SL, TP, NA, and n denote a thickness of a spacer layer between adjacent recording layers, a track pitch, a numerical aperture of an objective lens in the pickup, and a refractive index of the information storage medium, respectively.
 4. The apparatus of claim 1, wherein the information storage medium comprises a plurality of recording layers including the first and second recording layers, and a size of a recordable region of each of the plurality of recording layers decreases as a recording layer is farther away from the pickup.
 5. The apparatus of claim 1, wherein: each of the first and second recording layers include an optimum power control (OPC) area for performing a test to determine optimum recording power, and the OPC area of the first recording layer is larger than the OPC area of the second recording layer.
 6. The apparatus of claim 5, wherein the OPC area of the first recording layer is larger than the OPC area of second recording layer by an amount corresponding to about one-half a number of tracks through which a recording beam would pass on the second recording layer to record the data on the first recording layer.
 7. The apparatus of claim 5, wherein: the OPC area of the first recording layer is increased relative to the OPC of the second recording layer by about a number of tracks determined by an equation: ${{Number}\quad{of}\quad{tracks}} = \frac{{SL}\quad{\tan\left\lbrack {\sin^{- 1}\left( \frac{NA}{n} \right)} \right\rbrack}}{TP}$ where SL, TP, NA, and n denote a thickness of a spacer layer between adjacent recording layers, a track pitch, a numerical aperture of an objective lens in the pickup, and a refractive index of the information storage medium, respectively.
 8. The apparatus of claim 5, wherein the size of the user data area of each of the first and second recording layers decreases as a recording layer is farther away from the pickup.
 9. A method of reproducing data from an information storage medium with a plurality of recording layers using a pickup, the method comprising: reproducing a first amount of data from a recording layer located closest to the pickup; and reproducing lesser amounts of data than the first amount of data on other ones of the plurality of recording layers, the recorded amount of data on each of the other ones of the plurality of recording layers progressively decreasing from the recording layer closest to the pickup to a recording layer farthest from the pickup.
 10. The method of claim 9, wherein: an unrecorded region is disposed on inner and outer circumferences of a user data area of the other ones of the plurality of recording layers, and each unrecorded region corresponds to about one-half a number of tracks through which a recording beam passes on a recording layer closer to the pickup.
 11. The method of claim 9, wherein: an unrecorded region is disposed on inner and outer circumferences of a user data area of the other ones of the plurality of recording layers, wherein each unrecorded region of a first layer of the other ones of the plurality of recording layers comprises a number of tracks determined according to an equation: ${{Number}\quad{of}\quad{tracks}} = \frac{{SL}\quad{\tan\left\lbrack {\sin^{- 1}\left( \frac{NA}{n} \right)} \right\rbrack}}{TP}$ where SL, TP, NA, and n denote a thickness of a spacer layer between the plurality of recording layers, a track pitch, a numerical aperture of an objective lens, and a refractive index of the information storage medium, respectively.
 12. The method of claim 10, wherein a difference in the size of a user data area between adjacent recording layers corresponds to a respective difference in a size of the corresponding unrecorded regions of the adjacent layers.
 13. A method of reproducing data from a recordable information storage medium including a plurality of recording layers using a pickup, each recording layer having an optimum power control (OPC) area for performing a test in order to determine optimum recording power for the corresponding recording layer, the method comprising: reproducing data from a first one of the recording layers located closest to the pickup; and reproducing data from recording layers other than the first recording layer, wherein a size of the OPC area on each of the recording layers increases in the order of recording layers from closest to farthest from the pickup.
 14. The method of claim 13, wherein a second recording layer comprises unrecorded regions on inner and outer circumferences of a user data area, wherein each unrecorded region corresponds to about half a number of tracks through which a test beam passes on the first recording layer to record on the second recording layer.
 15. The method of claim 13, wherein a second recording layer comprises unrecorded regions on inner and outer circumferences of a user data area, wherein each unrecorded region corresponds a number of tracks determined according to an equation: ${{Number}\quad{of}\quad{tracks}} = \frac{{SL}\quad{\tan\left\lbrack {\sin^{- 1}\left( \frac{NA}{n} \right)} \right\rbrack}}{TP}$ where SL, TP, NA, and n denote a thickness of a spacer layer between adjacent recording layers, a track pitch, a numerical aperture of an objective lens, and a refractive index of the information storage medium, respectively.
 16. A reproducing apparatus comprising: a pickup that irradiates a beam onto an information storage medium, the information storage medium including a plurality of recording layers; a recording/reproducing signal processor that receives a beam reflected from the information storage medium through the pickup for signal processing; and a controller that controls the pickup to reproduce data from the recording layers, wherein data is not recorded on predetermined regions located on inner and outer circumferences of a user data area of the recording layers on which data is being reproduced except for one of the recording layers closest to the pickup.
 17. A reproducing apparatus comprising: a pickup that irradiates a beam onto an information storage medium, the information storage medium including a plurality of recording layers, each recording layer having an optimum power control (OPC) area for performing a test in order to determine optimum recording power for the corresponding recording layer; a recording/reproducing signal processor that receives a beam reflected from the information storage medium through the pickup for signal processing; and a controller that controls the pickup to reproduce data from the recording layers, wherein the data is not recorded on predetermined regions located on inner and outer circumferences of the OPC area of the recording layers on which data is being reproduced except one of the recording layers closest to the pickup.
 18. A method of reproducing data from a recordable information storage medium with a plurality of recording layers using a pickup, the method comprising: reproducing data on one of the recording layers located closest to the pickup; and reproducing data on inward recording layers other than the one recording layer, wherein a size of a recorded region on the inward recording layers decreases in the order of recording layers from closest to farthest from the pickup.
 19. A reproducing apparatus comprising: a pickup that irradiates a beam onto an information storage medium, the information storage medium including a plurality of recording layers; a recording/reproducing signal processor that receives a beam reflected from the information storage medium through the pickup for signal processing; and a controller that controls the pickup to reproduce data from the recording layers, where a size of a recorded region decreases according to a distance of a respective recording layer from the pickup.
 20. A method of reproducing data from an optical disk having a plurality of recording layers using an optical pickup having an objective lens which irradiates a light beam onto the recordable optical disk, the method comprising: reproducing data from recordable areas of the recording layers, the recordable layers each having an optimum power control (OPC) area for performing a test to determine an optimum recording power to a respective layer, the OPC area of an inwardly disposed one of the plurality of recording layers is assigned a greater area than the OPC area of an outwardly disposed one of the plurality of recording layers closer to the optical pickup.
 21. The method of claim 20, wherein the OPC areas are assigned so that a difference between the OPC area of the inwardly disposed layer and the OPC of the outwardly disposed layer increases with an increasing numerical aperture of the objective lens, decreases with an increasing track pitch of the recordable optical disk, decreases with an increasing refractive index of the recordable optical disk and increases with an increase in spacing between the inwardly disposed layer and the outwardly disposed layer.
 22. A reproducing apparatus comprising: an optical pickup comprising an objective lens which irradiates a light beam onto a recordable optical disk, the optical disk having a plurality of recording layers; and a controller which controls the optical pickup and which reproduces the data read from recordable areas of the recording layers, wherein each recording layer includes an optimum power control (OPC) area for performing a test to determine an optimum recording power for the respective layer, and the OPC area of an inwardly disposed one of the plurality of recording layers has a greater area than the OPC area of an outwardly disposed one of the plurality of recording layers closer to the optical pickup.
 23. The apparatus of claim 22, wherein: the OPC areas are assigned so that a difference between the OPC area of the inwardly disposed layer and the OPC of the outwardly disposed layer increases with an increasing numerical aperture of the objective lens, decreases with an increasing track pitch of the recordable optical disk, decreases with an increasing refractive index of the recordable optical disk and increases with an increase in spacing between the inwardly disposed layer and the outwardly disposed layer. 